Bridging wireless and wired media in a computer network

ABSTRACT

In one embodiment, a transmitting node may be configured to transmit a wireless advertisement frame over a computer network, wherein the frame includes a source address of a reachable node being advertised, a destination address to which the reachable node is to be advertised, a transmitter address of the transmitting node, and a receiver address of a wireless access point to which the wireless advertisement frame is to be received. Also, the wireless access point may be configured to receive the wireless advertisement frame from the network, and in response, transmit a reflected wireless advertisement frame having the source address of the reachable node, the destination address to which the reachable node is to be advertised, a transmitter address of the access point, and a receiver address that indicates the reflected frame is to be accepted by any appropriate receiver excluding the transmitting node.

TECHNICAL FIELD

The present disclosure relates generally to computer networks, and, moreparticularly, to bridging wireless and wired media in a computernetwork.

BACKGROUND

Computer networks and home entertainment networks are beginning to seethe emergence of an arbitrary collection of devices with Ethernetinterfaces, some hard-wired and some wireless. For example, networks mayinterconnect a variety of different protocol-based stations or devices,such as in accordance with IEEE Std. 802.3 (physical), IEEE Std. 802.11(wireless), Multimedia over Coax Alliance (MoCA), Ether/DSL (DigitalSubscriber Line), etc. In particular, a wireless station attached to anaccess point may, itself, be a bridge to other wireless and/or wiredmedia. That is, a wireless device may interconnect with a networkwirelessly, and may act as a bridge to other wireless/wired devices sothose devices may also be interconnected with the network.

In the event, however, that an 802.11 wireless station is also a bridge,it cannot work properly within defined standards of the network. Onereason is that the access point reflects all broadcasts (e.g.,advertisements) issued by a station back to all stations on the wirelessmedium. A station that is not a bridge can discard the reflectedbroadcast based on the presence of its own source address in the frame.However, a wireless station that is also bridge is unable to determinethat the reflections originated at itself. As such, the wireless bridgesare unable to determine whether to suppress the reflection as its ownadvertisement, or to learn that a device that may have been coupled to(i.e., located behind) the wireless bridge has moved to a new locationin the network.

Various workarounds to this problem have lead to various anomalies inthe behavior of the network. For instance, there may be extended lossesof connectivity (e.g., five minutes), where no such loss would occur inan all-wired network. Also, there may be excessive flooding of unknownframes (causing possible loss of quality guarantees), as well asduplicate delivery of multicasts and/or flooded unicasts in situationswhere there would be none in an all-wired network. Certain proprietaryprotocols may be used to overcome these issues, such as the successivetransmission of broadcasts from the access point individually to eachwireless station, instead of one broadcast to all stations. However,such proprietary protocols do not conform to industry standards (e.g.,IEEE standards), and thus are not widely available to networks otherthan those executing the specific proprietary protocols.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and further advantages of the invention may be betterunderstood by referring to the following description in conjunction withthe accompanying drawings in which like reference numerals indicateidentically or functionally similar elements, of which:

FIG. 1 illustrates an example computer network;

FIG. 2 illustrates an example network device/node;

FIGS. 3A and 3B illustrate an example advertisement exchange;

FIG. 4 illustrates an example advertisement frame; and

FIGS. 5A and 5B illustrate an example procedure for bridging wirelessand wired media.

DESCRIPTION OF EXAMPLE EMBODIMENTS Overview

According to embodiments of the disclosure, a transmitting node may beconfigured to transmit a wireless advertisement frame over a computernetwork, wherein the frame includes a source address of a reachable nodebeing advertised, a destination address to which the reachable node isto be advertised, a transmitter address of the transmitting node, and areceiver address of a wireless access point to which the wirelessadvertisement frame is to be received. Also, the wireless access pointmay be configured to receive the wireless advertisement frame from thenetwork, and in response, transmit a reflected wireless advertisementframe having the source address of the reachable node, the destinationaddress to which the reachable node is to be advertised, a transmitteraddress of the access point, and a receiver address that indicates thereflected frame is to be accepted by any appropriate receiver excludingthe transmitting node.

Description

A computer network typically comprises a plurality of interconnectedentities. An entity may consist of any network device, such as a serveror end station, that “sources” (i.e., transmits) or “sinks” (i.e.,receives) data frames. A common type of computer network is a local areanetwork (“LAN”) which typically refers to a privately owned networkwithin a single building or campus. LANs typically employ a datacommunication protocol (LAN standard), such as Ethernet, FDDI or tokenring, that defines the functions performed by the data link and physicallayers of a communications architecture (i.e., a protocol stack).

One or more intermediate network devices are often used to couple LANstogether and allow the corresponding entities to exchange information.For example, a bridge may be used to provide a “bridging” functionbetween two or more LANs or end stations. Typically, the bridge is acomputer and includes a plurality of ports that are coupled to the LANsor end stations. Ports used to couple bridges to each other aregenerally referred to as a trunk ports, whereas ports used to couplebridges to LANs or end stations are generally referred to as accessports. The bridging function includes receiving data from a sendingentity at a source port and transferring that data to at least onedestination port for forwarding to a receiving entity.

Although bridges may operate at various levels of the communicationprotocol stack, they typically operate at Layer 2 (L2) which, in the OSIReference Model, is called the data link layer and includes the LogicalLink Control (LLC) and Media Access Control (MAC) sub-layers. Dataframes at the data link layer typically include a header containing theMAC address of the entity sourcing the message, referred to as thesource address, and the MAC address of the entity to whom the message isbeing sent, referred to as the destination address. To perform thebridging function, L2 bridges examine the MAC destination address ofeach data frame received on a source port. The frame is then switchedonto the destination port(s) associated with that MAC destinationaddress.

Other devices, commonly referred to as routers, may operate at highercommunication layers, such as Layer 3 (L3) of the OSI Reference Model,which in Transmission Control Protocol/Internet Protocol (TCP/IP)networks corresponds to the Internet Protocol (IP) layer. Packets at theIP layer also include a header which contains an IP source address andan IP destination address. Routers or L3 switches may re-assemble orconvert received data frames from one LAN standard (e.g., Ethernet) toanother (e.g. token ring). Thus, L3 devices are often used tointerconnect dissimilar subnetworks.

FIG. 1 is a schematic block diagram of an example computer network 100illustratively comprising nodes/devices, such as bridges 110, one ormore access points 120, and other devices 130, interconnected by links(physical 104 and wireless 106) as shown. For instance, Bridge A may beinterconnected physically with device X, and may also act as an accesspoint for wireless communication with Bridges B and D, and device C.Also, Bridge B may be physically interconnected with device Y, andBridge D may be physically interconnected with device Z. Those skilledin the art will understand that any number of nodes, devices, links,etc. may be used in the computer network, and that the view shown hereinis for simplicity. Those skilled in the art will also understand thatwhile the embodiments described herein are described generally, they mayapply to any network configuration within an Autonomous System (AS) orarea, or throughout multiple ASes or areas, etc. The computer network100 of FIG. 1 is meant for illustration purposes only and is not meantto limit the embodiments described herein.

Frames 150 may be exchanged among the nodes/devices of the computernetwork 100 using predefined network communication protocols such as theTransmission Control Protocol/Internet Protocol (TCP/IP), User DatagramProtocol (UDP), Asynchronous Transfer Mode (ATM) protocol, Frame Relayprotocol, Internet Packet Exchange (IPX) protocol, etc. As such, eachbridge includes one or more ports/interfaces for receiving andforwarding the network messages.

FIG. 2 is a schematic block diagram of an example node/device 200 thatmay be advantageously used with one or more embodiments describedherein, e.g., as a bridge 110, access point 120, and/or other device 130(such as a wireless receiver). The device comprises a plurality ofnetwork interfaces or ports 210, one or more processors 220, and amemory 240 interconnected by a system bus 250. The networkinterfaces/ports 210 contain the mechanical, electrical, and signalingcircuitry for communicating data over physical links coupled to thenetwork 100. The network interfaces/ports may be configured to transmitand/or receive data (frames 150) using a variety of differentcommunication protocols over physical links or wireless links. Forexample, such communication protocols may include, inter alia, TCP/IP,UDP, ATM, synchronous optical networks (SONET), wireless protocols(e.g., IEEE Std. 802.11), Frame Relay, Ethernet (e.g., IEEE Std. 802.3),Fiber Distributed Data Interface (FDDI), etc. Notably, a networkinterface/port 210 may also be used to implement one or more virtualnetwork interfaces, such as for Virtual Private Network (VPN) access orVirtual LANs (VLANs), as will be understood by those skilled in the art.Illustratively, the handling of frames 150 within the networkinterfaces/ports 210 may conform to a protocol stack (not shown) thatdefines the functions performed by the data link and physical layers ofa communications architecture.

The memory 240 comprises a plurality of storage locations that areaddressable by the processor(s) 220 and the network interfaces/ports 210for storing software programs and data structures associated with theembodiments described herein. The processors 220 may comprise necessaryelements or logic adapted to execute the software programs andmanipulate the data structures 248. An operating system 242 (e.g., theInternetworking Operating System, or IOS™, of Cisco Systems, Inc.),portions of which are typically resident in memory 240 and executed bythe processor(s), functionally organizes the node by, inter alia,invoking network operations in support of software processes and/orservices executing on the device. These software processes and/orservices may comprise communication process/services 243, access pointprocess 244 (for access point 120), and bridging process/protocols 246(for bridges 110). It will be apparent to those skilled in the art thatother processor and memory means, including various computer-readablemedia, may be used to store and execute program instructions pertainingto the inventive technique described herein.

Communication process/services 243 contain computer executableinstructions executed by the processors 220 to perform functionsprovided by one or more communication protocols, such as variousswitching or forwarding/routing protocols. These functions may beconfigured to manage switching databases (e.g., spanning tree instances,a data structure 248), filtering databases (FDBs, a data structure 248),or forwarding information databases (FIBs, a data structure 248)containing, e.g., data used to make switching/forwarding decisions. Inparticular, as part of communication process/services 243, wirelessdevices may utilize communication protocols set forth in various, e.g.,standardized, wireless protocols, such as IEEE Std. 802.11. Forinstance, if a device is enabled to act as an access point 120 (e.g.,Bridge A), then the device may have an access point process 244 directedto communicating wirelessly with one or more other wireless devices ofthe network 100. Also, any device in the network 100 that has more thanone Ethernet interface (port 210) may be configured to act as a bridgein order to ensure connectivity between the devices, particularly wherethere may be many Ethernet-like links, such as 802.3, 802.11, MoCA,Ether/DSL, etc., as mentioned above. Accordingly, bridges 110 in thenetwork may have corresponding bridging process/protocols 246, such asin accordance with IEEE Std. 802.1 (e.g., 802.1D and/or 802.1Q).

Notably, with an all-wired network (e.g., assuming for this example thatwireless links 106 are physical links 104 in FIG. 1), current protocols,as will be understood by those skilled in the art, generally function asexpected to advertise reachability. For instance, assume that Node Zsends out a broadcast message, which is received by Bridge D. Bridge Dmay then relay the broadcast to the shared physical medium (assume thataccess point 120 is a shared physical link between devices A, B, C, andD). Accordingly, Bridges A and B receive the broadcast, learn thedirection to source Node Z, and relay the broadcast to Node X and NodeY, respectively. Node C also receives the broadcast as well. Inparticular, Bridge D does not see the broadcast frame reflected backtowards itself. In this manner, should Node Z be moved to a newlocation, e.g., to where Node Y is located (behind Bridge B), then NodeZ may send another broadcast, which Bridge B relays into the sharedmedium. Bridge D now receives a broadcast from Bridge B showingconnectivity with Node Z, so Bridge D now knows that Node Z has moved,and learns the new direction to source Node Z, accordingly.

Based on a mixed-media network, however, such as the wired (104) andwireless (106) links in FIG. 1, various problems are presented duringthe situation described above. For example, assume again that Node Zsends out a broadcast message, which is received by Bridge D. Bridge Dmay then relay the broadcast wirelessly to the access point 120 onBridge A (access point A). (FIG. 3A illustrates an exampleframe/advertisement exchange 300 a.) The access point A reflects thereceived broadcast onto the wireless “links”, which may be received byany wireless receiver, such as Bridge B, Node C, and also Bridge D.(FIG. 3B illustrates an example frame/advertisement exchange 300 b.)Bridges A and B and Node C receive the broadcasts, and learn thedirection to source Node Z. Since Bridge D receives the reflectedbroadcast frame, and since the wireless frame was originated by itself,Bridge D should suppress the frame. However, using current wirelessprotocols, Bridge D is unable to determine whether Node Z's broadcast isbeing reflected back from the access point, or that Node Z has moved andis being re-broadcast from a new Bridge (e.g., Bridge B). Specifically,a conventional three-address frame (not shown) may comprise the sourceaddress of the reachable node (e.g., Node Z), the destination address towhich the reachable node is to be advertised (e.g., broadcast within thenetwork 100), and the transmitter address of the access point (e.g.,access point A). In other words, upon receiving the wirelessadvertisement frame from an access point 120, a bridge is currentlyunable to determine whether the advertised node is behind itself, or hasmoved. (Note that wireless devices that are not bridges have not had toaddress these concerns, e.g., Node C, as those wireless devices are onlyinterconnected to the network 100 wirelessly through a singleconnection, i.e., do not share the same issues.)

As an illustration of a “real-world” network that may be affected by theabove problems, assume that Node Z is a television (TV) with a singleEthernet port, and is playing a unicast program from a satellitereceiver (e.g., Bridge D). If the TV is moved to another wiredconnection, e.g., to where Node X is located behind Bridge A, then thesatellite receiver (Bridge D) may continue to send the unicast programto where the TV (Node Z) was previously, thus “blackholing” the program.One manner to inform the network 100 of the location change is to haveBridge A send a Topology Change Notification (TCN) when the TVassociates with its new bridge (Bridge A itself), and all bridgesunlearn (most of) their addresses. During a brief interruption untiladdresses are relearned, however, all traffic is flooded everywhere inthe network 100, not just the satellite receiver's unicast programtraffic. This wide-scale flooding of all traffic may result in glitchesin the flows in the network (e.g., due to bandwidth saturation, as maybe appreciated by those skilled in the art).

One solution to this problem is to not use the TCN, but instead sendsome broadcasts and/or multicasts (e.g., address resolution protocol, or“ARP” requests) from the moved TV (Node Z). These broadcast frames maybe seen by the bridges in the network 100, and are used to relearn thenode's (TV's) new location, thus alleviating the flooding burstsmentioned above. However, as mentioned above, when Bridge D (thesatellite receiver) receives this broadcast, the bridge “thinks itknows” where the TV is (that is, behind itself), so it will suppress thebroadcasts thinking they are reflections from a wireless access point.Because of this, nothing happens between the satellite receiver and theTV until a timeout occurs (e.g., a five-minute MAC table entry timeout),and the satellite starts flooding the unicast program again to find(relearn) the location of the TV. This additional period ofdisconnection between the satellite receiver and TV as well as theflooding of a satellite program into the entire network 100 is bothcumbersome and inefficient. Unfortunately, there are currently no knownsolutions to these problems that are in accordance with current and/orstandardized networking protocols.

Bridging Wireless and Wired Media

Currently, as mentioned above, IEEE Std. 802.11 wireless framesgenerally only use three address fields (e.g., source, destination, andtransmitter addresses). However, there is a recent four-address formatproposed for 802.11, which includes descriptions of each field,including an additional field designed to contain a receiver addressindicating which devices should receive the associated frame. Althoughthe frame format is defined, there is no specification in 802.11 of howstations or access points might use this format. According to one ormore embodiments described herein, the four-address format may be usedin a manner that is consistent with standardized protocols in thenetwork (e.g., 802.1, 802.3, 802.11, etc.), and that alleviates theproblems described above that are associated with mixed-media (wired andwireless) networks. In particular, in accordance with one or moreembodiments herein, the receiver address within reflected advertisementframes from an access point 120 may comprise a special multicast addressthat indicates that all receivers except a particular receiver shouldaccept the frame. In this manner, a bridge (e.g., Bridge D) may be ableto distinguish between reflected frames originated by itself, orreflected frames originated by another bridge.

Illustratively, the techniques described herein may be performed byhardware, software, and/or firmware, such as various communicationprocesses/services 243, e.g., in conjunction with access point process244 (for access point 120) and bridging process 246 (for bridges 110).These processes and/or services may be configured to operate inaccordance with certain protocols (e.g., standards, such as IEEE Stds.802.1, 802.3, and 802.11), and in accordance with the techniquesdescribed herein to operate according to a four-address wirelessadvertisement frame.

In particular, FIG. 4 illustrates an example four-address frame formatof a wireless advertisement frame 400 (a or b, described below). Forinstance, source address 410 generally contains the address of areachable node being advertised in the frame (e.g., Node Z), anddestination address 420 may contain an address to which the reachablenode is to be advertised (e.g., broadcast, multicast, or unicastaddresses), both such as in accordance with a bridged Ethernet frame, aswill be understood by those skilled in the art. Also, in accordance witha wireless frame (802.11), a transmitter address 430 may contain anaddress of a transmitting node from which the wireless advertisementframe is sent/transmitted (e.g., depending on which device actuallytransmits the frame). In addition, a receiver address 440, as describedherein, indicates which devices should receive the associated frame, asin accordance with the purpose of the receiver address field as definedby the IEEE (802.11).

Operationally, upon receiving a broadcast from a reachable node (e.g.,Node Z), a wireless bridge (e.g., Bridge D) may transmit this broadcast(referred to herein as a wireless advertisement frame 400 a) onto thewireless media 106 of the network 100 toward an access point 120 (e.g.,access point A, see FIG. 3A). Specifically, the wireless Bridge D, atransmitting node, may populate the four addresses of a wirelessadvertisement frame 400 a according to the description above. That is,illustratively, the source address 410 is Node Z, the destinationaddress 420 is a broadcast, multicast, or unicast address (dependingupon the desired breadth of advertisement), and the transmitter address430 is the address of the transmitting node, Bridge D. In addition, thereceiver address 440 for frame 400 a is a unicast address of the accesspoint A.

The wireless access point A may then receive the advertisement frame 400a, and may distribute the advertisement to other interconnected nodes inthe network 100. For instance, if the wireless access point 120 isinterconnected with one or more nodes via physical wires (e.g., Node X),then the wireless access point 120 (also a bridge 110) may transmit awired advertisement frame (not shown) having the source address of thereachable node, the destination address to which the reachable node isto be advertised, and the transmitter address of the access point (thatis, in accordance with 802.3 Ethernet). In addition, access pointprocess 244 of the access point may be configured to transmit a“reflection” or “reflected” wireless advertisement frame (400 b) intothe network over wireless links 106 in order to wirelessly relay thereceived advertisement (e.g., from Bridge D).

Particularly, from the access point 120 (e.g., access point A), thereflected wireless advertisement frame 400 b (see FIG. 3B) may again betransmitted with the four-address format of FIG. 4. However, reflectedframe 400 b from the access point 120 may modify the address fieldsaccordingly. For instance, while the source address 410 and destinationaddress 420 may remain the same as in frame 400 a, the transmitteraddress 430 is changed to the address of the access point. (Note that aunicast address itself may be broadcast in address 420 when the unicastaddress location within the network is unknown, as will be appreciatedby those skilled in the art.) In addition, in accordance with one ormore embodiments described herein, the receiver address 440 of thereflected wireless advertisement frame 400 b may indicate that thereflected frame is to be accepted by any appropriate receiver excludingthe transmitting node (e.g., all except Bridge D, from transmittingaddress 430 of frame 400 a). In other words, the receiver address 440 isa special (e.g., multicast) address meaning “everyone except station Xshould accept this frame,” where station X in this example is thetransmitting node, Bridge D.

Illustratively, the receiver address 440 in the reflected frame 400 bmay indicate any appropriate receiver excluding the transmitting node bycombining a range of multicast addresses along with an associationidentifier (AID) of the transmitting node. For instance, the receiveraddress 440 may be a fixed “OUI” (organization/company ID, oralternatively, an “OID”) supplied by proprietary ownership or, ifstandardized, by the IEEE (802.1 or 802.11), representing a multicastaddress for nodes that are to receive the advertisements, plus the AIDof “station X” (e.g., Bridge D). Generally, the AID is a 16-bit integerthat is obtained by the transmitting node (Bridge D) as a part ofassociating with the access point 120. An illustrative address field is48 bits long (6 bytes), where the upper 22 bits are the OUI, and thelower 24 bits remain for specific use by an organization/standardcommittee. If the AID consumes the lower 16 bits of the field, then theupper 32 bits may be used to represent a fixed range of multicast MACaddresses (proprietary or standardized) to which receivers maysubscribe.

As such, an appropriate receiver configured to receive advertisementsregarding the reachable node (e.g., a wireless receiver in communicationwith access point A) may be configured to subscribe to (accept)multicast addresses (e.g., all) corresponding to receivingadvertisements regarding the reachable node, except for those with thereceiver's own AID. For instance, Bridge B, Bridge D, and Node C mayeach be configured to receive traffic for multicast addressestransmitted by access point A, and to accept the reflected wirelessframes 400 b from the access point A. However, should any of thereceivers (particularly Bridge B or Bridge D) determine that it isexcluded from a particular frame, e.g., determining that its specificAID is located within the receiver address 440 (at a location used todesignate excluded addresses), then that receiver may ignore orotherwise suppress the received frame 400 b (e.g., Bridge D).

Notably, for broadcasts or multicasts originated by the bridge 110 thatis the access point 120 (e.g., A), no other device need be notified tosuppress the advertisement 400 b. Accordingly, the receiver address 440may be either a special AID value indicating the access point (accesspoint A's AID), the broadcast address, or not present (that is, usingthe three-address format). In this manner, any receiving device mayaccept the frame, where the frame still conforms to the embodimentsdescribed herein.

Moreover, there may be network configurations that have one or moredevices that are not configured to accept/understand recent four-addressframes 400 as described above. That is, these devices may be configuredto only accept previous three-address frames. Accordingly, the wirelessaccess point (bridge A) may determine that one or more receivers in thenetwork 100 are unable to parse four addresses in a reflected wirelessadvertisement frame 400 b, such as through a simple configuration (e.g.,a ‘yes’ or ‘no’ configuration) or more complex dynamic discoverytechniques. In response to having such devices, the wireless accesspoint may broadcast the four-address frame 400 b as described above, andmay also broadcast a conventional three-address frame. For instance, aconventional three-address frame (not shown) may comprise the sourceaddress of the reachable node (e.g., 410), the destination address towhich the reachable node is to be advertised (e.g., 420), and thetransmitter address of the access point (e.g., 430). By transmittingboth three- and four-address frames, both types of devices receive anadvertisement, and each type may ignore/discard the other'sadvertisements.

FIG. 5A illustrates an example procedure for bridging wireless and wiredmedia in accordance with one or more embodiments described herein. Theprocedure 500 starts at step 505, and continues to step 510, where atransmitting node (e.g., bridge D) receives a broadcast from a reachablenode (e.g., node Z). The transmitting node (bridge D) may then transmita wireless advertisement frame 400 a in step 415 onto wireless networkmedia. In particular, the wireless advertisement frame 400 a maycomprise, as described above, a source address 410 of a reachable nodebeing advertised (node Z), a destination address 420 to which thereachable node is to be advertised (e.g., broadcast), a transmitteraddress 430 of the transmitting node from which the wirelessadvertisement frame is received (bridge D), and a receiver address 440of the access point to which the wireless frame is intended (e.g., anaccess point, bridge A).

In step 520, the wireless access point (bridge A) receives the wirelessadvertisement frame 400 a, and in response, may transmit a reflectedwireless advertisement frame 400 b in step 525. In particular, asdescribed above, the reflected wireless advertisement frame may comprisea source address 410 of the reachable node (node Z), a destinationaddress 420 to which the reachable node is to be advertised (broadcast),a transmitter address 430 of the access point (bridge A), and a receiveraddress 440 that indicates the reflected frame 400 b is to be acceptedby any appropriate receiver excluding the transmitting node (e.g.,multicast to any receiver, except bridge D). For instance, as mentionedabove, the exclusion may include an association ID of the transmittingnode (bridge D) in addition to a multicast address to which theremaining (i.e., non-bridge D receivers) may subscribe.

In step 530, the procedure 500 continues to FIG. 5B, which begins atstep 535 (from FIG. 5A), and continues to step 540, where receivers(transmitting node/bridge D or other receivers, e.g., B, C, etc.)receive the reflected wireless advertisement frame 400 b. In step 545,the receivers may determine whether the receiver address 430 ofreflected wireless advertisement frame 400 b excludes the receivingnode, that is, whether the receiving node is the excluded transmittingnode (bridge D). If the receiver is excluded in step 550 (i.e., thereceiver is bridge D in the example), then in step 555, the receiver(transmitting node) suppresses the reflected wireless advertisementframe 400 b. Conversely, if the receiver is not excluded in step 550,then in step 560, the receivers (not the transmitting node) may acceptthe reflected wireless advertisement frame 400 b, e.g., as describedabove, having been an appropriately configured receiver.

As noted herein, certain networks 100 may comprise one or more nodes notconfigured to receive the four-address advertisement frames 400. If so,in step 565, the wireless access point may also transmit additionalthree-address reflected wireless advertisement frames. Also, should theaccess point be interconnected with one or more devices over physicallinks, in step 570 the access point may transmit wired advertisementframes over those physical links. The procedure 500 ends in step 575,having bridged wireless and wired media in the network 100.

Advantageously, the novel techniques described herein bridge wirelessand wired media in a computer network. By defining and utilizing afourth address field in wireless frames, particularly a receiver addressthat excludes the originating (to the wireless media) transmitting node,the novel techniques enable building a bridged network in which wirelessmedia are interior links, as opposed to simply providing access to thenetwork. In particular, the techniques described above may be embodiedin a manner that is consistent with existing bridges and protocols(e.g., standards 802.1, 802.3, and 802.11). For instance, a wiredstation in a mixed wireless/wired network typically does not know thatit is part of a mixed-media network. Therefore, introducing newprocedures and protocols to correct deficiencies of the combination of802.11, 802.1, and 802.3 is not appropriate. Moreover, the dynamicaspects of one or more embodiments described herein alleviate the needfor cumbersome and inefficient manual configuration.

While there have been shown and described illustrative embodiments thatbridge wireless and wired media in a computer network, it is to beunderstood that various other adaptations and modifications may be madewithin the spirit and scope of the present invention. For example, theembodiments have been shown and described herein with relation tovarious standardized protocols, such as 802.1, 802.3, and 802.11.However, the embodiments of the invention in their broader sense are notso limited, and may, in fact, be used with other suitable wired and/orwireless protocols.

Notably, while the one or more embodiments described herein define aparticular format of the receiver address 420, other formats may be usedin accordance with the techniques above. For instance, the order ofmulticast addresses and AIDs may be reversed, or any other format may beused that conforms to the wireless standards provided for the fourthreceiver address 420, i.e., which devices should receive the associatedframe. (For example, if the receiver address 420 were simply populatedby the transmitting node's MAC address, e.g., Bridge D's, then thereceiver address is not being used within the true meaning of thestandardized fourth address, i.e., “who should receive this frame.”Instead, the devices in the network 100 would have to be adjustedcontrary to the meaning of the standards such that receiver address 420refers to “everyone but this address should receive this frame.” Usingthe techniques described herein, however, the meaning of the receiverframe is maintained, e.g., “who should receive this frame, except thisdevice”, thus accomplishing the suppression of own-multicasts whileremaining within the scope of standardized protocols, e.g., 802.11.)

The foregoing description has been directed to specific embodiments ofthis invention. It will be apparent, however, that other variations andmodifications may be made to the described embodiments, with theattainment of some or all of their advantages. For instance, it isexpressly contemplated that the components and/or elements describedherein can be implemented as software, including a computer-readablemedium having program instructions executing on a computer, hardware,firmware, or a combination thereof. Also, electromagnetic signals may begenerated to carry computer executable instructions that implementaspects of the present invention over, e.g., a wireless data link or adata network, such as the Internet. Accordingly this description is tobe taken only by way of example and not to otherwise limit the scope ofthe invention. Therefore, it is the object of the appended claims tocover all such variations and modifications as come within the truespirit and scope of the invention.

1. A method, comprising: receiving, at a wireless access point of acomputer network, a wireless advertisement frame having a source addressof a reachable node being advertised, a destination address to which thereachable node is to be advertised, a transmitter address of atransmitting node from which the wireless advertisement frame isreceived, and a receiver address of the access point; and transmitting,from the wireless access point, a reflected wireless advertisement framehaving the source address of the reachable node, the destination addressto which the reachable node is to be advertised, a transmitter addressof the access point, and a receiver address that indicates the reflectedframe is to be accepted by any appropriate receiver excluding thetransmitting node.
 2. The method as in claim 1, further comprising:receiving the reflected wireless advertisement frame at the transmittingnode; and suppressing the reflected wireless advertisement frame at thetransmitting node in response to the receiver address of the reflectedwireless advertisement frame indicating any appropriate receiverexcluding the transmitting node.
 3. The method as in claim 1, furthercomprising: receiving the reflected wireless advertisement frame at areceiver; and accepting the reflected wireless advertisement frame atthe receiver in response to the receiver not being the transmitting nodeexcluded in the receiver address of the reflected wireless advertisementframe.
 4. The method as in claim 1, wherein the transmitting node is awireless bridge.
 5. The method as in claim 1, further comprising:determining, at the wireless access point, that one or more receiversare unable to parse four addresses in a reflected wireless advertisementframe; and in response; transmitting, from the wireless access point, anadditional three-address reflected wireless advertisement frame havingthe source address of the reachable node, the destination address towhich the reachable node is to be advertised, and the transmitteraddress of the access point.
 6. The method as in claim 1, wherein thewireless access point is interconnected with one or more nodes viaphysical wires.
 7. The method as in claim 6, further comprising;transmitting, from the wireless access point, a wired advertisementframe having the source address of the reachable node, the destinationaddress to which the reachable node is to be advertised, and thetransmitter address of the access point.
 8. The method as in claim 1,further comprising: indicating any appropriate receiver excluding thetransmitting node by combining a range of multicast addresses along withan association identifier of the transmitting node.
 9. The method as inclaim 1, wherein an appropriate receiver is a receiver configured toreceive advertisements regarding the reachable node.
 10. The method asin claim 9, further comprising: configuring the appropriate receiver tosubscribe to one or more multicast addresses corresponding to receivingadvertisements regarding the reachable node.
 11. The method as in claim1, wherein the destination address is a multicast address.
 12. Themethod as in claim 1, wherein the destination address is a unicastaddress.
 13. A method, comprising: transmitting, from a transmittingnode of a computer network, a wireless advertisement frame having asource address of a reachable node being advertised, a destinationaddress to which the reachable node is to be advertised, a transmitteraddress of the transmitting node, and a receiver address of a wirelessaccess point to which the wireless advertisement frame is to bereceived; and receiving, at the transmitting node, a reflected wirelessadvertisement frame from the wireless access point, the reflectedwireless advertisement frame having the source address of the reachablenode, the destination address to which the reachable node is to beadvertised, a transmitter address of the access point, and a receiveraddress that indicates the reflected frame is to be accepted by anyappropriate receiver excluding the transmitting node.
 14. The method asin claim 13, further comprising: suppressing the reflected wirelessadvertisement frame at the transmitting node in response to the receiveraddress of the reflected wireless advertisement frame indicating anyappropriate receiver excluding the transmitting node.
 15. The method asin claim 13 further comprising: receiving a reflected wirelessadvertisement frame at the transmitting node; and accepting thereflected wireless advertisement frame at the transmitting node inresponse to the transmitting node not being excluded in the receiveraddress of the reflected wireless advertisement frame.
 16. The method asin claim 13, wherein the transmitting node is a wireless bridge.
 17. Themethod as in claim 13, further comprising: configuring the transmittingnode to subscribe to one or more multicast addresses corresponding toreceiving advertisements regarding one or more other reachable nodes.18. A system, comprising: a transmitting node coupled to a computernetwork; a wireless access point coupled to the computer network; andone or more receivers coupled to the computer network; wherein: thetransmitting node is configured to transmit a wireless advertisementframe having a source address of a reachable node being advertised onthe computer network, a destination address to which the reachable nodeis to be advertised, a transmitter address of the transmitting node, anda receiver address of the wireless access point to which the wirelessadvertisement frame is to be received; and the wireless access point isconfigured to receive the wireless advertisement frame, and in response,transmit a reflected wireless advertisement frame having the sourceaddress of the reachable node, the destination address to which thereachable node is to be advertised, a transmitter address of the accesspoint, and a receiver address that indicates the reflected frame is tobe accepted by any appropriate receiver excluding the transmitting node.19. The system as in claim 18, wherein the transmitting node is furtherconfigured to: receive the reflected wireless advertisement frame; andsuppress the reflected wireless advertisement frame in response to thereceiver address of the reflected wireless advertisement frameindicating any appropriate receiver excluding the transmitting node. 20.The system as in claim 18, wherein the receivers are configured to:receive the reflected wireless advertisement frame; and accept thereflected wireless advertisement frame in response to the receiver notbeing the transmitting node excluded in the receiver address of thereflected wireless advertisement frame.